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TRANSCRIPT
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Thermal Rectification In Asymmetric Graphene Ribbons
Nuo Yang1, Gang Zhang
2, a)and Baowen Li
3,1, b)
1Department of Physics and Centre for Computational Science and Engineering,
National University of Singapore, 117542 Singapore
2Institute of Microelectronics, A*STAR, 11 Science Park Road, Singapore Science Park II,
Singapore 117685, Singapore
3NUS Graduate School for Integrative Sciences and Engineering, 117597 Singapore
ABSTRACT
In this paper, heat flux in graphene nano ribbons has been studied by using molecular
dynamics simulations. It is found that the heat flux runs preferentially along the direction
of decreasing width, which demonstrates significant thermal rectification effect in the
asymmetric graphene ribbons. The dependence of rectification ratio on the vertex angle
and the length are also discussed. Compared to the carbon nanotube based one-
dimensional thermal rectifier, graphene nano ribbons have much higher rectification ratio
even in large scale. Our results demonstrate that asymmetric graphene ribbon might be a
promising structure for practical thermal (phononics) device.
a)Electronic mail:[email protected]
b)Electronic mail:[email protected]
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The graphene is a two-dimensional crystal consisting of a single atomic layer of
carbon. It has attracted immense interests recently, mostly because of its unusual
electronic properties [1]. Graphene ribbons (GRs), the narrow layers of graphene are
particularly interesting as promising elements in nanoelectronics. It has been shown that
many of the electronic properties of GR can be modulated by its size and shape [2-5]. In
addition, the thermal properties of graphene are also important both for fundamental
understanding of the underlying physics in low-dimensional system and for applications.
Superior thermal conductivity has been observed in graphene [6, 7], which has raised the
exciting prospect of using graphene structures for thermal (phononics) devices.
Traditionally, phonons are considered as heat carriers. Recently, it is found that phonons
can be also used to carry and process information [8-17]. More importantly, different
thermal (phononic) devices such as thermal rectifier, thermal transistor, thermal logic
gate, and thermal memory, have been conceptualized.All these have not only made the
control of heat flow possible, but also made it possible to use phonons to carry and
process information.
Similar to electronic counterpart, the thermal rectifier also plays a vital role in
phononics circuit [16]. Thermal rectifier from nano structures has been theoretically
studied [14, 17] and also experimentally tested [18] in carbon nanotube (CNT) based
systems. All the structures studied so far are basically one-dimensional or quasi-one-
dimensional systems. A natural question comes promptly: Can we extend the thermal
rectification characteristic to two-dimensional structure, such as in GR? In this Letter, we
should investigate numerically (by using molecular dynamics) the direction dependent
heat flux in asymmetric structural GRs, and discussed the impacts of GR shape and size
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on the rectification ratio. Our study may inspire experimentalists to develop GR based
thermal (phononic) devices.
In our simulations, classical non-equilibrium molecular dynamics (MD) method is
adopted. The potential energy is a Stillinger-Weber type potential for bonding interaction
between carbon atoms, which include both two-body and three-body potential terms. This
force field potential is developed from fitting experimental parameters for graphite by
Abraham and Batra [19] and the accuracy of this potential is demonstrated in MD
simulations in graphitic structures [20].
Figure 1 shows two different GR structures: trapezia shaped GR (TGR) and two
rectangular GRs with different width (RGR). In order to establish a temperature gradient
along the longitudinal direction, the GR is coupled with Nos-Hoover heat bathes on the
two end layers. Atoms in the same layer have the same z coordinate. The atoms of 1st
andNth (N is the number of layers) layers are frozen corresponding to fixed boundary
condition. The atoms of 2nd and N-1th layers are coupled with Nos-Hoover heat bathes
[21, 22], whose temperatures are topT and bottomT respectively. In this Letter, in order to
avoid any artificial effect induced by the choice of heat baths, all the calculations are
performed with the same Nos-hoover heat bath parameter (thermostat response time) on
the two ends.
The velocity Verlet algorithm is used to integrate the differential equations of motions.
In general, the temperature, TMD, is calculated from the kinetic energy of atoms according
to the Boltzmann distribution [23]. It is worth pointing outthat this approach is valid only
at high temperature (T>>TD, TDis the Debye temperature). When the system temperature
islower than the Debye temperature, it is necessary to apply a quantum correction to the
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MD calculated temperature. The difference between the MD calculated temperature and
quantum corrected temperature depends on the Debye temperature of the system.
Although some theoretical studies have been performed on the Debye temperature of
graphene, the results have been controversial. For instance, from 1000 K to 2000 K are
reported. [24-26] The concerns of the current paper are the heat flux and rectification
effects (a related change of heat flux) which do not depend on the accurate value of
temperature, instead they depend on the temperature difference. Therefore, we dont do
the quantum correction to TMD in this work. The heat flux along the GR is defined as the
energy transported along it in unit time. [17] MD simulations are performed long enough
such that the system reaches a stationary state when the local heat flux is a constant. All
results given here are obtained by averaging 4106
time steps. The time step is 0.4 fs.
In this Letter, we set the temperature of top (the short end) as ( )= 10
TTtop and that
of bottom (the long end) as ( )+= 10TTbottom , where 0T is the average temperature, and
is the normalized temperature difference between the two ends. Therefore, the bottom of
GR is at a higher temperature when 0> , and the top has a higher temperature when
0 , the heat flux increases steeply with ;
while in the region 0
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This is similar to the rectification phenomena observed in carbon nanocone (CNC)
structures [17], which was explained well by match/mismatch of the phonon spectra
between the atomic layers at the two ends. To show the rectification effect quantitatively,
the thermal rectification is defined as,
( )%100R
-
-
+
J
JJ
where+
J is the heat current from bottom to top corresponds to 0> and-
J is the heat
current from top to bottom when 0
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In the following, we explore the size dependence of rectification of TGR, as the
rectification of TGR is higher than that of RGR. First, the dependence of the rectification
ratio on vertex angle, , is explored. The length of TGR, L, is fixed at 3.4 nm, and W top is
fixed at 0.4 nm. is changed from 26o
to 78o, which corresponds to Wbot from 1.7 to 5.9
nm. Figure 3(a) shows that the rectification increases with vertex angle, , due to the
increases of asymmetry. As illustrated in Figure 3(b), the heat fluxes,+
J and
J , of TGR
increase as increases. The increase of+
J is higher than the increase of
J , which leads
to the increase of the rectification ratio. Figure 3(a) shows the rectification ratio increase
from 90% to 240% (here ||=0.3) as the increasing of from 26o to 60 o and converges
when o60 .
Next, we study the impact of length on the rectification ratio. We change the value of
L from 3.4 nm (30 layers) to 13.5 nm (120 layers), while the value of are fixed at 60o.
The top end and the angle of TGR are fixed while the length L and bottom end Wbot are
changed. Figure 3(c) shows the dependence of rectification on the length. At short length,
the small increase of length induces large reduction in rectification ratio. Contrast to the
high dependence at the short length range, the rectification versus length curve is close to
flat when length is longer than 5.1 nm. As illustrated in figure 3(d), the increase of
J is
larger than that of+
J as L increase from 3.4 nm to 5.1 nm. Both+
J and
J are
converged when L is longer than 5.1nm, which leads to the rectification ratio as a
constant of 92%. This is different from previous results of one-dimensional structures. In
the molecular junction typed CNT thermal rectifier [14], the rectification decreases
quickly as device length is increased, because the role of the interface is suppressed in
large system. However, in the GR rectifier proposed here, high rectification can be
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achieved in the practical length scale, adds the feasibility of constructing thermal rectifier
with graphene.
In conclusion, we have demonstrated excellent thermal rectification efficiency in
asymmetric graphene ribbons. It is shown that the graded geometric asymmetry is of
remarkable benefit to increase the rectification ratio. The convergence of rectification
ratio on the increase of length is of particular importance forpractical thermal (phononics)
application. Compared to the CNT [14] and CNC [17] rectifier, the rectification ratio in
TGR is much higher. In contrary to the previous studies of thermal rectifiers which are
constructed with one-dimensional structures, our results demonstrate the two-dimensional
structures can also be used in thermal management.
This work is supported in part by an ARF grant, R-144-000-203-112, from the
Ministry of Education of the Republic of Singapore, and Grant R-144-000-222-646 from
National University of Singapore.
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Figure 1. Schematic pictures of the two different graphene ribbons (GR) structures:
trapezia shaped GR (TGR) and two-rectangular GRs with different width (RGR). The top
layer is the first layer, with width of W top, and the bottom layer is the Nth layer, with
width of Wbot. HereNis the total number of layers. The length isL, while in RGR, each
segment is with the same length ofL/2.
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Figure 2. (Color on-line) (a) Heat flux J versus for the TGR and RGR. (b)
Rectifications versus for the TGR and RGR. Here, L=3.4 nm (30 layers), o60= ,Wtop
= 0.42 nm (2 atoms), Wbot = 4.2 nm (20 atoms), and T0 = 300 K.
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Figure 3. (Color on-line) (a) and (b) Rectifications and heat fluxes of TGR with different
, here L = 3.4 nm (30 layers), Wtop = 0.42 nm, T0 = 300 K and 3.0= . (c) and (d)
Rectifications and heat fluxes of TGR for different length, here o60= ,Wtop =0.42 nm,
T0 = 300 K and 3.0= .